[0001] The present invention relates to a method for attaching a ceramic matrix composite
(CMC) shroud and discourager to a metal outer shroud in such as way as to allow for
adjustment of the CMC shroud and/or the discourager, for example during installation
or due to expansion and/or contraction, while preventing hot gas in the turbine from
reaching the outer metal shroud. The method involves utilizing a key slot arrangement
for connecting the CMC shroud and discourager to the outer metal shroud.
BACKGROUND OF THE INVENTION
[0002] It is well known that industrial gas turbine and aircraft engine shrouds operate
in a high temperature environment and require cooling methods to obtain a useful design
life cycle. An alternative to using a metal shroud with cooling air is to use a CMC
material for the shroud, thus eliminating the required cooling of the shroud due to
the CMC's superior temperature capability over metal.
[0003] Prior attempts to solve this problem have been made using conventional metal seals
or complex assemblies. For example, one approach has been to use multiple pins to
hold the CMC or to use hooks formed in the CMC component. Other prior art uses a CMC
bonded to a ceramic core with pins going through the core.
[0004] These arrangements utilizing pins have two distinct disadvantages, namely (1) additional
cooling air is required to maintain design life of the seal, and (2) higher cost due
to the use of expensive high temperature custom made metal pins. Metal pins at the
flow-path also require cooling air to meet the required design life, thus reducing
the benefit of the CMC.
EP1965030 discloses a ceramic seal segment for a shroud ring of a rotor of a gas turbine engine,
the ceramic seal segment positioned radially adjacent the rotor and characterised
by being a hollow section that defines an inlet and an outlet for the passage of coolant
therethrough.
[0005] A more effective way of mounting the CMC shroud to the outer metal shroud and preventing
hot gases from contacting the metal outer shroud is desirable. The present invention
seeks to satisfy that desire.
BRIEF DESCRIPTION OF THE INVENTION
[0006] The invention provides a shroud assembly for use in a turbine according to claim
1. The shroud assembly has an outer shroud with a side proximate to a flow of an operative
fluid of the turbine, the side being provided with a boss and an aperture extending
through the boss. An inner shroud is positioned between the side of the outer shroud
proximate to the flow of operative fluid and the operative fluid flow of the turbine.
The inner shroud is provided with an aperture which is dimensioned to fit over the
boss.
[0007] A discourager assembly is enclosed within the inner shroud and is positioned offset
from the inner shroud so as to extend past the inner shroud and into an inner shroud
of a neighboring shroud assembly. In an embodiment, the discourager assembly has a
discourager with an aperture and a plate member with an aperture mounted on a surface
of the discourager. The discourager aperture and the plate member aperture are aligned
with the inner shroud aperture and the boss to facilitate insertion of a bolt to fasten
the assembly together.
[0008] In another embodiment, the boss in the outer shroud is upstanding above the plane
of the surface of the outer shroud in which the boss is present. The boss generally
has a square profile when viewed in plan, and typically has rounded corners.
[0009] In a further embodiment, the apertures in the inner shroud and the discourager are
rectangular shaped in which the longer opposite sides of the rectangle are separated
by a distance which is slightly larger than the distance between the opposite sides
of the square boss in the outer shroud. In this way, the rectangular slot of the shroud
or the discourager can be placed over the square boss such that the upstanding surfaces
of the boss can be in contact with, and slide relative to, the longer sides of the
rectangular aperture, thereby allowing for adjustment of the position of the discourager
within the inner shroud.
[0010] In yet another embodiment, the plate member has at least one aperture which aligns
with the boss of the outer shroud and the rectangular aperture of the inner shroud.
In a typical embodiment, the plate member is provided with two apertures which align
with two bosses and two rectangular apertures in the inner shroud.
[0011] In a further embodiment, the plate member is accommodated in a recess in a surface
of the discourager. In an alternative embodiment, the plate member is housed in an
internal space within the discourager.
[0012] The apertures in the plate member are typically threaded to accommodate a fastening
means such as a bolt. In this way, the inner shroud/discourager assembly can be mounted
to the outer shroud by way of a bolt threadedly engaged with the plate member without
the bolt force being applied directly to the inner shroud. Adjustment of the discourager
within the inner shroud can be achieved by sliding relative movement of the discourager
or the inner shroud by virtue of the rectangular apertures, prior to tightening with
the bolt.
[0013] The size and stiffness of the plate member is used to tune the amount of radial spring
force that is applied to the inner shroud and discourager. The bolt is contained in
the outer shroud block where cooling is not necessary. Typically, the inner shroud
is fabricated from a ceramic matrix composite (CMC) which allows for greatly reduced
cooling air requirements.
[0014] Use of a CMC inner shroud with no cooling air additionally affords the advantage
of an engine performance benefit in efficiency and output. The invention enables the
use of CMC inner shrouds at a much lower cost structure than has previously been possible.
The attachment method of the invention does not require the use of custom pins made
from exotic materials, and thus reduces the overall cost of the associated hardware.
In addition, the attachment is shielded from the hot gas environment, thereby significantly
reducing the cooling and purge air requirements of the attachment compared to what
has been done previously.
BRIEF DESCRIPTION OF THE DRAWINGS
[0015]
Figure 1 is a perspective view of an outer metal shroud assembly including a hollow
CMC inner shroud and discourager seal located internally of the CMC inner shroud;
Figure 2 is a cross-sectional end view of the outer metal shroud assembly of Figure
1 showing attachment of the CMC inner shroud and discourager seal assembly via a plate
member/bolt arrangement to a boss on a surface of the outer metal shroud;
Figure 3 is a view of the outer metal shroud assembly of Figure 1 from the underside
showing the plate member with two threaded apertures mounted on a surface of the discourager
and aligned with two bosses in the outer metal shroud;
Figure 4 is a view of the underside of the outer metal shroud showing upstanding generally
square bosses on the right hand side and a discourager on the left hand side with
a recess but without the plate member mounted in the recess;
Figure 5 is a perspective view of the discourager shown in Figure 4 but with the plate
member positioned in the discourager recess and having two threaded boss members in
the plate member which align with the bosses in the outer metal shroud;
Figure 6 is a perspective view of the CMC inner shroud showing a pair of rectangular
key slots which align with the bosses on the outer metal shroud and the boss members
on the plate member;
Figure 7 shows an alternative embodiment of the outer shroud assembly of Figure 1
from the underside showing an internal space or pocket in the discourager for housing
the plate member and showing two apertures which communicate with the internal space
and which align with the apertures in the plate member;
Figure 8 is an end view of the discourager shown in Figure 7 showing the internal
space with the plate member in position;
Figure 9 is a perspective view of the discourager of Figure 8;
Figure 10 is cross-section showing the discourager of Figure 8 without the plate showing
the internal space and two apertures communicating with the internal space;
Figure 11 is an alternative cross-section of the outer shroud assembly of Figure 7
showing the discourager with the internal space and the plate member within the internal
space, and a bolt extending through the boss of the outer metal shroud into the threaded
apertures of the plate member to tighten the CMC shroud and discourager up against
the outer metal shroud;
Figure 12 is a perspective view of an alternative embodiment of a discourager having
a male configured shiplap feature for permitting connection to a corresponding female
configured discourager;
Figure 13 shows discouragers of different units connected to each other via the shiplap
arrangement;
Figure 14 is an enlarged view of Box B in Figure 13;
Figures 15 and 16 are cross-sectional views of discouragers connected to each other
via the shiplap arrangement illustrated in Figure 12, one with the plate member present
(Figure 15) and one with the plate member absent (Figure 16).
DETAILED DESCRIPTION OF THE INVENTION
[0016] Referring to the drawings, Figure 1 is a perspective view of an outer shroud assembly
of the invention. The assembly includes an outer metal shroud 10 having an aperture
9 extending therethrough, a hollow CMC shroud 6 having apertures 14 therein (shown
in more detail in Figure 6) and a discourager seal 2 having apertures 11 therein (shown
in more detail in Figure 9) located internally of the CMC shroud 6.
[0017] Figure 2 is a cross-sectional end view of the outer shroud assembly of Figure 1,
and shows attachment of the CMC shroud 6 and discourager seal 2 via a plate member/bolt
arrangement to a boss 16 on a surface of the outer shroud 10. The apertures 11 of
discourager 2 are dimensioned such that bosses 16 on the outer metal shroud 10 fit
into the apertures 11. A metal plate member 4 having threaded apertures 5 is provided
in recess 7 in the discourager 2.
[0018] The assembly of the CMC shroud 6, the discourager 2 and the plate member 4 is mounted
to the outer metal shroud 10 by aligning apertures 14 in the CMC shroud, apertures
11 in the discourager and threaded apertures 5 in the plate member 4 over the bosses
16 in the outer metal shroud, passing a fastening means such as a bolt 8 through aperture
9 in the outer metal shroud 10, through the boss 16 and threadedly engaging with the
threaded apertures 5 of the plate member 4. Tightening the bolt 8 pulls the CMC shroud/discourager/plate
member assembly into tight contact with surface 12 of the outer metal shroud, as shown
in Figure 2.
[0019] The discourager and its function are disclosed in copending application serial number
12/576,386.
[0020] Figure 3 is a view of the outer shroud assembly 10 from the underside showing (for
ease of understanding, this is shown as if the CMC shroud 6 was transparent) the plate
member 4 with two threaded apertures 5, mounted in a recess 7 of the discourager 2.
In the embodiment shown, the threaded apertures 5 are formed as raised boss members
5 to provide extra thread length for the bolt 8.
[0021] Figure 3 illustrates the situation where there are two CMC shrouds 6 mounted to the
outer metal shroud with a small gap 13 therebetween. In this arrangement, the corresponding
discouragers disposed internally of the CMC shrouds are adjusted relative to the CMC
shrouds to create an overlap region 18 such that the gap 13 is essentially blocked
by the discourager. In this way, each discourager prevents hot gas from having a direct
line of sight to the metal outer shroud 10 and establishes a tortuous path through
the gap 13 to the outer metal shroud 10. This in turn allows for the use of conventional
metallic seals in the outer shroud 10 to provide for effective sealing of the secondary
flow leakages around the outer shroud 10.
[0022] Figure 4 is a view of the underside of the outer metal shroud 10 showing upstanding
generally square bosses 16 on the right hand side, and a discourager 2 on the left
hand side with a recess 7 but without the plate member 4 mounted in the recess 7.
Figure 5 is a perspective view of the discourager 2 shown in Figure 4 but with the
plate member 4 positioned in the discourager recess 7 and having two threaded raised
boss members 5 in the plate member 4 which align with the bosses 16 in the outer metal
shroud 10.
[0023] Figure 6 is a perspective view of the CMC shroud 6 showing a pair of rectangular
key slots 14 which are positioned to align with the bosses 16 on the outer metal shroud
10 and the boss members 5 on the plate member 4. Each rectangular key slot 14 is dimensioned
such that the distance separating the longer opposite sides of the rectangle is slightly
greater than the length of the sides of the square bosses 16 in order to allow the
key slots to fit over and slide relative to the square bosses 16 on the outer metal
shroud 10, thereby allowing for positional adjustment of the CMC shroud 6 with respect
to the outer metal shroud 10 because of differences in thermal expansion of the components
due to them being made from different materials, i.e. CMC expands differently than
metal.
[0024] In the embodiment shown in Figure 6, the rectangular key slots 14 are arranged in
the CMC shroud 6 such that the longitudinal axis of one rectangle (i.e., the axis
parallel to the longer sides of the rectangle) is perpendicular to the axis of the
other. This allows for additional positional adjustment of the CMC shroud 6 relative
to the outer metal shroud 10 for the same reasons as discussed above.
[0025] Figure 7 shows an alternative embodiment of the outer shroud assembly from the underside
showing an internal space or pocket 20 in the discourager 2 for housing the plate
member 4. The discourager 2 is provided with two apertures 11 which communicate with
the internal space 20 and which align with the apertures 5 in the plate member 4.
[0026] Figure 8 is an end view of the discourager 2 shown in Figure 7. In this view, the
plate member 4 is in position within the internal space 20.
[0027] Figure 9 is a perspective view of the discourager of Figure 8. The rectangular apertures
11 are positioned to align with the bosses 16 on the outer metal shroud 10 and the
boss members 5 on the plate member 4. Each rectangular aperture 11 is dimensioned
such that the distance separating the longer opposite sides of the rectangle is slightly
greater than the length of the sides of the square bosses 16 in order to allow the
apertures to fit over and slide relative to the square bosses 16 on the outer metal
shroud 10. This allows for positional adjustment of the discourager 2 in the axial
and tangential directions to the outer shroud 10 with respect to the CMC shroud 6
and the outer metal shroud 10, as discussed above.
[0028] Figure 10 is a cross-section showing the discourager 2 of Figure 8 without the plate
4. The internal space 20 is shown with two apertures 11 communicating with the internal
space 20.
[0029] Figure 11 is an alternative cross-section of the outer shroud assembly of Figure
7. In this arrangement, the discourager 2 is provided with internal space 20 and plate
member 4 within the internal space, and a bolt 8 extends through aperture 9 in the
boss 16 of the outer metal shroud 10 into the threaded apertures 5 of the plate member
4 to tighten the CMC shroud 6 and discourager 2 up against surface 12 of the outer
metal shroud 10.
[0030] Figure 12 is a perspective view of an alternative embodiment of a discourager 2 having
a male configured shiplap 24. This permits connection to a discourager provided with
a corresponding female portion 26, such as shown in Figures 13 and 14. Figure 14 is
an enlarged view of Box 7c in Figure 13.
[0031] Figures 15 and 16 are cross-sectional views of discouragers connected to each other
via a shiplap arrangement 24,26. In Figure 15, the plate member 4 is present and in
Figure 16, the plate member 4 is absent.
1. A shroud assembly for use in a turbine, the shroud assembly comprising:
an outer shroud (10) having a side proximate to a flow of an operative fluid of the
turbine, the side provided with a boss (16) and an outer shroud aperture (9) extending
through the boss (16);
an inner shroud (6) positioned between the side of the outer shroud proximate to the
flow of operative fluid and the operative fluid flow of the turbine, the inner shroud
provided with an inner shroud aperture (14) which is dimensioned to fit over the boss
(16); characterized by
a discourager assembly (2,4,5,11) enclosed within the inner shroud and mounted to
the outer shroud, the discourager assembly (2,4,5,11) positioned offset from the inner
shroud (6) so as to extend past the inner shroud (6) and into an inner shroud of a
neighboring shroud assembly.
2. A shroud assembly according to claim 1 , the discourager assembly comprising a discourager
(2) having a discourager aperture (11) and a plate member (4) having a plate member
aperture (5) which is preferably threaded mounted on a surface of the discourager,
the discourager aperture (11) and the plate member aperture (5) being aligned with
the inner shroud aperture and the boss, the plate member preferably comprising a raised
boss (16) through which said aperture extends.
3. The shroud assembly of claim 1 or claim 2, wherein the boss (16) is of a square configuration
and has raised side walls, and the inner shroud aperture (14) is preferably rectangular
and is dimensioned such that such that the distance separating the longer opposite
sides of the rectangle is slightly greater than the length of the sides of the square
boss, the rectangular inner shroud apertures being preferably arranged such that the
longitudinal axis of one rectangle is perpendicular to the axis of the other, the
discourager aperture being preferably rectangular and dimensioned such that the distance
separating the longer opposite sides of the rectangle is slightly greater than the
length of the sides of the square boss.
4. The shroud assembly of claim 2, wherein the plate member is mounted in a recess (7)
in a surface of the discourager (2).
5. The shroud assembly of claim 2, wherein the plate member is mounted in an internal
space (20) in said discourager (2).
6. The shroud assembly of any one of claims 2 to 5, wherein the discourager is provided
with a shiplap connector (24).
7. The shroud assembly of any one of claims 2 to 6, further comprising a bolt (8) extending
through the outer shroud aperture, the inner shroud aperture, the discourager aperture
and the plate member aperture to hold the shroud assembly together.
1. Ummantelungsanordnung zur Verwendung in einer Turbine, wobei die Ummantelungsanordnung
umfasst:
eine äußere Ummantelung (10) mit einer Seite in der Nähe einer Strömung eines Betriebsfluids
der Turbine, wobei die Seite mit einer Nabe (16) und einer äußeren Ummantelungsöffnung
(9) bereitgestellt ist, die sich durch die Nabe (16) erstreckt;
eine innere Ummantelung (6), die zwischen der Seite der äußeren Ummantelung in der
Nähe der Strömung eines Betriebsfluids und der Betriebsfluidströmung der Turbine angeordnet
ist, wobei die innere Ummantelung mit einer inneren Ummantelungsöffnung (14) bereitgestellt
ist, die so dimensioniert ist, dass sie über die Nabe (16) passt; gekennzeichnet durch
eine Abweiseranordnung (2, 4, 5, 11), die in der inneren Ummantelung eingeschlossen
und an der äußeren Ummantelung montiert ist, wobei die Abweiseranordnung (2, 4, 5,
11) von der inneren Ummantelung (6) versetzt angeordnet ist, sodass sie sich über
die innere Ummantelung (6) hinaus und in eine innere Ummantelung einer benachbarten
Ummantelungsanordnung erstreckt.
2. Ummantelungsanordnung nach Anspruch 1, wobei die Abweiseranordnung einen Abweiser
(2) mit einer Abweiseröffnung (11) und ein Plattenelement (4) mit einer Plattenelementöffnung
(5) umfasst, das vorzugsweise mit einem Gewinde auf einer Oberfläche des Abweisers
montiert ist, wobei die Abweiseröffnung (11) und die Plattenelementöffnung (5) mit
der inneren Ummantelungsöffnung und der Nabe ausgerichtet sind, wobei das Plattenelement
vorzugsweise eine erhöhte Nabe (16) umfasst, durch die sich die Öffnung erstreckt.
3. Ummantelungsanordnung nach Anspruch 1 oder Anspruch 2, wobei die Nabe (16) eine quadratische
Konfiguration hat und erhöhte Seitenwände aufweist und die innere Ummantelungsöffnung
(14) vorzugsweise rechteckig ist und so dimensioniert ist, dass der Abstand, der die
längeren gegenüberliegenden Seiten des Rechtecks trennt, etwas größer ist als die
Länge der Seiten der quadratischen Nabe, wobei die rechteckigen inneren Ummantelungsöffnungen
vorzugsweise so angeordnet sind, dass die Längsachse des einen Rechtecks senkrecht
zur Achse des anderen steht, wobei die Abweiseröffnung vorzugsweise rechteckig ist
und so dimensioniert ist, dass der Abstand, der die längeren gegenüberliegenden Seiten
des Rechtecks trennt, etwas größer ist als die Länge der Seiten der quadratischen
Nabe.
4. Ummantelungsanordnung nach Anspruch 2, wobei das Plattenelement in einer Aussparung
(7) in einer Oberfläche des Abweisers (2) montiert ist.
5. Ummantelungsanordnung nach Anspruch 2, wobei das Plattenelement in einem Innenraum
(20) in dem Abweiser (2) montiert ist.
6. Ummantelungsanordnung nach einem der Ansprüche 2 bis 5, wobei der Abweiser mit einem
Überfalzungsverbinder (24) bereitgestellt ist.
7. Ummantelungsanordnung nach einem der Ansprüche 2 bis 6, ferner umfassend einen Bolzen
(8), der sich durch die äußere Ummantelungsöffnung, die innere Ummantelungsöffnung,
die Abweiseröffnung und die Plattenelementöffnung erstreckt, um die Ummantelungsanordnung
zusammenzuhalten.
1. Ensemble de carénage destiné à être utilisé dans une turbine, ledit ensemble de carénage
comprenant :
un carénage externe (10) ayant un côté à proximité d'un écoulement d'un fluide opérationnel
de la turbine, le côté étant pourvu d'un bossage (16) et d'une ouverture de carénage
externe (9) s'étendant à travers le bossage (16) ;
un carénage interne (6) positionné entre le côté du carénage externe à proximité de
l'écoulement de fluide opérationnel et l'écoulement de fluide opérationnel de la turbine,
le carénage interne étant pourvu d'une ouverture de carénage interne (14) qui est
dimensionnée pour s'adapter sur le bossage (16) ; caractérisé par
un ensemble de dissuadeur (2,4,5,11) enfermé à l'intérieur du carénage interne et
monté sur le carénage externe, l'ensemble de dissuadeur (2,4,5,11) positionné en décalage
par rapport au carénage interne (6) de façon à s'étendre depuis le carénage interne
(6) et dans un carénage interne d'un ensemble de carénage voisin.
2. Ensemble de carénage selon la revendication 1, l'ensemble de dissuadeur comprenant
un dissuadeur (2) ayant une ouverture de dissuadeur (11) et un élément de plaque (4)
ayant une ouverture d'élément de plaque (5) qui est de préférence montée filetée sur
une surface du dissuadeur, l'ouverture de dissuadeur (11) et l'ouverture d'élément
de plaque (5) étant alignées avec l'ouverture de carénage interne et le bossage, l'élément
de plaque comprenant de préférence un bossage surélevé (16) à travers lequel s'étend
ladite ouverture.
3. Ensemble de carénage selon la revendication 1 ou la revendication 2, dans lequel le
bossage (16) est constitué d'une configuration carrée et possède des parois latérales
surélevées, et l'ouverture de carénage interne (14) est de préférence rectangulaire
et est dimensionnée de telle sorte que de telle sorte que la distance séparant les
plus longs opposés du rectangle est légèrement supérieure à la longueur des côtés
du bossage carré, les ouvertures rectangulaires du carénage interne étant de préférence
arrangées de telle sorte que l'axe longitudinal d'un rectangle est perpendiculaire
à l'axe de l'autre, l'ouverture de dissuadeur étant de préférence rectangulaire et
dimensionnée de telle sorte que la distance séparant les plus longs opposés du rectangle
est légèrement supérieure à la longueur des côtés du bossage carré.
4. Ensemble de carénage selon la revendication 2, dans lequel l'élément de plaque est
monté dans un évidement (7) dans une surface du dissuadeur (2).
5. Ensemble de carénage selon la revendication 2, dans lequel l'élément de plaque est
monté dans un espace interne (20) dans ledit dissuadeur (2).
6. Ensemble de carénage selon l'une quelconque des revendications 2 à 5, dans lequel
le dissuadeur est pourvu d'un connecteur à feuillure (24).
7. Ensemble de carénage selon l'une quelconque des revendications 2 à 6, comprenant en
outre un boulon (8) s'étendant à travers l'ouverture de carénage externe, l'ouverture
de carénage interne, l'ouverture de dissuadeur et l'ouverture de l'élément de plaque
pour maintenir conjointement l'ensemble de carénage.